• DECEMBER 2019 Fluid Flow Classifications What Are Fluids? – Lesson 3 Fluid Statics versus Fluid Dynamics • Fluids can be at rest or in motion. • Fluid statics is the study of fluids at rest (no motion). ‐ Fluid statics is commonly referred to as hydrostatics. • Fluid dynamics is the study of fluids in motion. ‐ Fluid dynamics of liquids is called hydrodynamics. ‐ Fluid dynamics of compressible gases is called gas dynamics. 2 Unsteady versus Steady Flow • Nearly all fluid motions observed in nature are inherently unsteady (time dependent). ‐ Fluid unsteadiness exists at a range of scales from very tiny to macroscopic. The random, mixed motion we often observe is called turbulence. • In many cases, we can ignore (or model) small-scale unsteadiness and consider the fluid motion as only a Boundary layer edge Inviscid zone function of space. Fluid motion is time- independent: velocity, pressure, and temperature do not change with time at a given point. This is the U(y) 훿 steady-state assumption. Viscous zone • For the purpose of modeling fluid motion, the steady-state assumption can be used to obtain Steady-state boundary layer model for flow over a flat plate useful and practical engineering solutions. ‐ Effects of turbulence can be modeled so that the simplified steady-state solution yields accurate results for skin friction and heat transfer. We will discuss this topic in more detail later in this course. 3 Uniform versus Non-Uniform Flow • Uniform Flow is a fluid flow in which characteristics and parameters remain unchanged with distance along the flow path. ‐ A steady flow through a long straight pipe of a constant diameter is an Uniform Flow example of uniform flow. • Non-uniform Flow is a flow in which characteristics and parameters vary and are different at different locations along the flow path. ‐ A steady flow through a pipe with bends or a pipe with a variable diameter exemplifies a non-uniform flow. Non-uniform Flow 4 Rotational versus Irrotational Flow • Rotation flow is a fluid flow in which fluid particles moving along the flow path also rotate about their respective axes. • Irrotational flow is flow in which fluid particles moving along the flow path do not undergo rotation. Rotational flow Irrotational flow 5 Laminar versus Turbulent Flow • Laminar Flow ‐ At low speeds, fluid particles move in a smooth, layered fashion (“lamina”). ‐ The flow appears uniform with no substantial mixing of the fluid. This is laminar flow. • Turbulent Flow ‐ At higher speeds, fluid particles begin to exhibit random fluctuations and move in a chaotic, “tangled” fashion. ‐ Flow appears non-uniform and significant mixing of fluid occurs. This is turbulent flow. • Fluid flow can undergo a transition from laminar to turbulent flow such that both states of fluid motion are observed. Knowing where this transition occurs is a Turbulent challenging question in fluid mechanics. Laminar flow flow 6 Incompressible versus Compressible Flow • Incompressible Flow – In an incompressible flow, the volume of a given fluid parcel does not change (compress). ‐ This implies that density is uniform throughout the fluid. ‐ It is a reasonable assumption for all liquid flows and low-speed gas flows. • Compressible Flow – In a compressible flow, the volume of a given fluid parcel can change (compress) with position. ‐ This implies that density will vary throughout the fluid, usually in accordance with a thermodynamic equation of state. Incompressible flow ‐ Compressible flows are further classified according to speed of fluid relative to the speed of sound waves. This ratio is non- dimensional and is called the Mach number (Ma). • For Ma < 1, the flow is subsonic. Pressure waves in the flow can propagate in all directions. • For Ma > 1, the flow is supersonic. Pressure waves can compress to form shock waves, which propagate in the downstream direction only. Compressible flow 7 Flow Configurations • External Flow ‐ An external flow is defined here as a flow over an object in an unconfined domain. ‐ Viscous effects are typically important only in the vicinity of the External flow over a sedan object. Away from the object, the flow is essentially inviscid. ‐ Examples: flow over aircraft, projectiles, ground vehicles. • Internal Flow ‐ An internal flow is defined as a flow which is confined by walls, partitions. and other boundaries. ‐ Viscous effects in this case extend across the entire passage ‐ Examples: flow in pipes, ducts, enclosures, nozzles. Internal flow through the Circle of Willis, a joining area of several arteries at the bottom side of the brain 8 Summary • We have examined some characteristics of fluid motion, and how flows exhibit different behavior based on: ‐ Steady-state versus unsteady ‐ Uniform and non-uniform flows ‐ Rotational and irrotational flows ‐ Incompressible versus compressible flow ‐ Laminar versus turbulent flow ‐ Flow geometry and configuration (external versus internal flows) 9 .